Seals in steam turbine

ABSTRACT

A seal structure for a steam turbine is provided, which is capable of suppressing transfer of heat generated by a friction between a rotating portion and a fixed portion to the rotating portion and of suppressing an increase in the temperature of the rotating portion. A labyrinth seal device serves to suppress the amount of steam leaking from a clearance present between each stator blade (fixed portion) of the steam turbine and a rotor (rotating portion). The seal structure for the steam turbine is formed to ensure that permeable spacers made of a permeable metal are provided on the rotor and a seal stationary body and face respective seal fins provided in the labyrinth seal device.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a seal structure for a steam turbine.

2. Description of the Related Art

A power plant generates electricity by rotating a turbine (steam turbine) by steam which a steam generator such as a boiler generates. As steam turbines used in such a power plant, a high-pressure turbine, an intermediate-pressure turbine and a low-pressure turbine are provided in the order from the upstream side of flow of the steam. The steam used for rotating the low-pressure turbine is introduced into a condenser through an exhaust hood. The steam is then condensed by the condenser and turned into water. The water is returned to the steam generator.

In the steam turbine constituting a part of the power plant, each of stator blades fixed to the inner side of a casing is arranged between rotor blades that rotate with a rotor. The rotor blade and the stator blade form a stage.

The steam introduced into the casing flows in the casing of the steam turbine. The steam then alternately passes the stator blades and the rotor blades (that are fixed to the rotor rotatably held by the casing) and expands so as to rotate the rotor. After passing through the rotor blade provided on the most downstream side of the rotor, i.e., the last-stage rotor blade, the steam is discharged outside of the casing.

In the steam turbine, the steam causes the rotor blades to rotate and thereby causes the rotor to rotate. In order to efficiently utilize the steam, it is required to minimize a clearance between a fixed portion and a rotating portion, such as clearances between the stator blades and the rotor, in order to reduce the amount of steam leaking from the clearance as much as possible and to improve a sealing property. However, when the clearance between the rotating portion and the fixed portion is minimized, the frequency of contacts between the rotating portion and the fixed portion increases. Frictional heat generated by the contacts may increase the temperature of a contact part of the rotating portion. When the contact part of the rotation portion increases in temperature due to the frictional heat, a temperature distribution of the rotating portion (in a rotational circumferential direction of the rotating portion) is not uniform, so that a rotor shaft may be bent by heat or the rotating portion may vibrate. When the amplitude of the vibrating motion is large, the steam turbine needs to be stopped in some cases.

In order to cope with the abovementioned problems, a technique relating to a seal structure is disclosed (for example, refer to JP-A-2002-228013 (refer to FIG. 1)). In the technique described in JP-A-2002-228013, a labyrinth seal device having a fin (seal fin) is conventionally provided between a rotating portion such as a rotor and a fixed portion such as a stator blade; and a member (abradable member) that has an excellent cutting property and faces the fin is used. According to the technique described in JP-A-2002-228013, in the case where the labyrinth seal device is designed to ensure that a clearance between the fin and the abradable member is minimized, when the fin and the abradable member contact each other for some reason, the abradable member is cut by the fin. This can suppress generation of frictional heat due to the contact of the fin with the abradable member. In addition, it is possible to suppress a vibrating motion of the rotor shaft due to nonuniform heat bending (occurring due to an increase in the temperature of the rotor) of the rotor shaft.

JP-A-2007-16704 discloses a technique relating to a seal structure having a heat insulating layer for suppressing transfer of heat to a rotating portion. According to the technique described in JP-A-2007-16704, the heat insulating layer is located between the rotating portion and a fin provided at the rotating portion, for example. This arrangement suppresses transfer of frictional heat (to the rotating portion) generated by a contact of the rotating portion with a fixed portion and suppresses a vibrating motion of a rotor shaft due to nonuniform heat bending of the rotor shaft.

SUMMARY OF THE INVENTION

In each of the techniques disclosed in JP-A-2002-228013 and JP-A-2007-16704, when the rotating portion continuously rotates for a long period of time, the frictional heat is gradually accumulated. The temperature of the abradable member or the temperature of the heat insulating layer increases. The accumulated heat is slowly transferred to the rotating portion. The temperature of the rotating portion gradually increases. The rotor shaft may vibrate due to nonuniform heat bending of the rotor shaft.

It is, therefore, an object of the present invention to provide a seal structure for a steam turbine. The seal structure is capable of suppressing an increase in the temperature of a rotating portion even when the rotating portion continuously rotates for a long period of time.

In order to accomplish the object, the seal structure for a steam turbine uses permeable spacers made of a permeable metal.

The present invention can provide the seal structure for a steam turbine, which is capable of suppressing an increase in the temperature of the rotating portion even when the rotating portion continuously rotates for a long period of time.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a systematic diagram showing a power plant having a steam turbine according to an embodiment of the present invention;

FIG. 2A is a diagram showing the configuration of a part of the steam turbine;

FIG. 2B is an enlarged view of an X portion shown in FIG. 2A;

FIG. 3 is an enlarged view of a Y portion shown in FIG. 2B;

FIG. 4A is a diagram showing a high-low labyrinth seal device in which a seal stationary body has seal fins;

FIG. 4B is a diagram showing a high-low labyrinth seal device in which a rotor has seal fins;

FIG. 5 is a schematic diagram showing a tip portion of a rotor blade;

FIG. 6 is a diagram showing a structure in which the tip portion of the rotor blade has seal fins;

FIG. 7 is a diagram showing a structure in which a nozzle diaphragm outer ring has seal fins and the rotor blade has other seal fins at the tip portion thereof.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

An embodiment of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a systematic diagram showing a power plant having a steam turbine according to the present embodiment. As shown in FIG. 1, the power plant 1 includes a boiler 10, a steam turbine 2 (a high-pressure turbine 12, an intermediate-pressure turbine 14, and a low-pressure turbine 16), a generator 18 and a condenser 20. A rotor 2 a of the low-pressure turbine 16 is connected to a drive shaft 22 of the generator 18. The generator 18 is driven by rotation of the low-pressure turbine 16 to generate electricity.

The boiler 10 is a steam generator and has a reheater 24 therein. The boiler 10 is connected to an inlet side of the high-pressure turbine 12 through a tube 26. An outlet side of the high-pressure turbine 12 is connected to the reheater 24 of the boiler 10 through a tube 28. The reheater 24 is connected to an inlet side of the intermediate-pressure turbine 14 through a tube 30. An outlet side of the intermediate-pressure turbine 14 is connected to an inlet side of the low-pressure turbine 16 through a tube 32.

Each of the tubes 26 and 30 has a control valve B. The control valve B of the tube 26 is controlled by a controller 54 and serves to control the amount of steam St to be introduced into the high-pressure turbine 12. The control valve B of the tube 30 is controlled by the controller 54 and serves to control the amount of steam St to be introduced into the intermediate-pressure turbine 14.

The steam St generated by the boiler 10 is introduced into the low-pressure turbine 16 through the high-pressure turbine 12 and the intermediate-pressure turbine 14 to cause the rotor 2 a provided in the low-pressure turbine 16 to rotate. The steam St that causes the rotor 2 a to rotate and is discharged from the low-pressure turbine 16 is introduced into the condenser 20 through an exhaust hood 3. The steam St is then condensed and turned into water by the condenser 20. After that, the water is delivered to a feed water heater 21 and then heated by the feed water heater 21. The heated water is reintroduced into the boiler 10 (that is the steam generator) through another feed water heater (not shown), a high-pressure water pump (not shown) and the like.

FIG. 2A is a diagram showing the configuration of a part of the steam turbine. FIG. 2B is an enlarged view of an X portion shown in FIG. 2A. FIG. 3 is an enlarged view of a Y portion shown in FIG. 2B.

Since the high-pressure turbine 12, the intermediate-pressure turbine 14 and the low-pressure turbine 16 (which are shown in FIG. 1) constitute the steam turbine 2, the present invention can be applied to the high-pressure turbine 12, the intermediate-pressure turbine 14 and the low-pressure turbine 16.

As shown in FIG. 2A, the steam turbine 2 has the rotor 2 a. A plurality of rotor blades 2 b is fixed to the rotor 2 a in a circumferential direction of the rotor 2 a. The steam turbine 2 also has a casing 2 d and stator blades 2 c. The casing 2 d houses the rotor 2 a and the rotor blades 2 b. The stator blades 2 c are fixed to the casing 2 d via nozzle diaphragm outer rings 3 b. The rotor blades 2 b and the stator blades 2 c are alternately arranged in an axial direction of the rotor 2 a to form stages.

When the steam St generated by the boiler 10 (refer to FIG. 1) is introduced into the casing 2 d, the steam St expands and passes between the stator blades 2 c and the rotor blades 2 b alternately to cause the rotor 2 a to rotate. The steam St passes through the rotor blade 2 b located on the most downstream side of the rotor 2 a, i.e., the last-stage rotor blade 2 b, followed by being discharged outside of the casing 2 d.

In the thus configured steam turbine 2, the steam St flowing in the casing 2 d causes the rotor blades 2 b to efficiently rotate. It is therefore required to improve properties of seals between rotating portions (including the rotor 2 a and the rotor blades 2 b) and fixed portions (including the casing 2 d and the stator blades 2 c) and suppress the amount of steam leaking from clearances provided between the rotating portions and the fixed portions.

A clearance is provided between the rotor 2 a and each of nozzle diaphragm inner rings 3 a. The nozzle diaphragm inner rings 3 a allow for a rotational motion of the rotor 2 a. The nozzle diaphragm inner rings 3 a are located at tip portions of the stator blades 2 c. The clearances may cause leakage of the steam St introduced in the stator blades 2 c. In order to suppress the amount of the leaking steam, a seal device such as a labyrinth seal device 3 c is typically provided in the vicinity of the rotor 2 a and of the nozzle diaphragm inner rings 3 a to ensure that a clearance between the rotor 2 a and each stator blade 2 c is set to be small to improve the seal property.

FIG. 2B is the enlarged view of the X portion shown in FIG. 2A and shows an example of the labyrinth seal device. As shown in FIG. 2B, a seal stationary body 3 c 1 having a plurality of seal fins 3 c 2 is engaged with and fixed to the nozzle diaphragm inner ring 3 a. The seal stationary body 3 c 1 has grooves 3 c 3 arranged at a predetermined interval. The seal fins 3 c 2 are respectively caulked in and fixed to the grooves 3 c 3. In addition, the rotor 2 a has grooves 2 a 2 arranged at a predetermined interval. Seal fins 2 a 1 are respectively caulked in and fixed to the grooves 2 a 2. The seal fins 3 c 2 and the seal fins 2 a 1 alternately overlap each other in the axial direction of the rotor 2 a.

In this way, the labyrinth seal device 3 c is composed of the seal stationary body 3 c 1, the seal fins 3 c 2 and the seal fins 2 a 1.

In a conventional technique, the seal fins 3 c 2 are not in contact with the rotor 2 a, and the seal fins 2 a 1 are not in contact with the seal stationary body 3 c 1. Thus, a sufficient clearance is provided between each of the seal fins 3 c 2 and the rotor 2 a, and a sufficient clearance is provided between each of the seal fins 2 a 1 and the seal stationary body 3 c 1, to prevent a contact between each of the seal fins 3 c 2 and the rotor 2 a and a contact between each of the seal fins 2 a 1 and the seal stationary body 3 c 1 and to thereby allow for a rotational motion of the rotor 2 a. However, steam leaks from these clearances resulting in steam leakage loss. This reduces the efficiency of the steam turbine 2 (refer to FIG. 1).

In the present embodiment, on the other hand, permeable spacers 4 made of permeable metal are provided between the respective seal fins 3 c 2 and the rotor 2 a and between the respective seal fins 2 a 1 and the seal stationary body 3 c 1.

The labyrinth seal device 3 c shown in FIG. 2B is configured to ensure that the permeable spacers 4 face (are provided between) the rotor 2 a and the respective seal fins 3 c 2 fixed to the seal stationary body 3 c 1, and the other permeable spacers 4 face (are provided between) the seal stationary body 3 c 1 and the respective seal fins 2 a 1 fixed to the rotor 2 a.

In the configuration of the labyrinth seal device 3 c, the permeable spacers 4 are provided on the rotor 2 a (rotating portion) and face the seal fins 3 c 2, and the other permeable spacers 4 are provided on the seal stationary body 3 c 1 (fixed portion) and face the seal fins 2 a 1. The seal stationary body 3 c 1 is engaged with and fixed to the nozzle diaphragm inner rings 3 a of the casing 2 d.

A method for setting the permeable spacers 4 on the rotor 2 a and setting the permeable spacers 4 on the seal stationary body 3 c 1 is not limited. For example, the permeable spacers 4 may be brazed on and fixed to the rotor 2 a and the seal stationary body 3 c 1.

In addition, the permeable spacers 4 are provided on the rotor 2 a and along the circumference of the rotor 2 a to ensure that the permeable spacers 4 respectively face tip portions of the seal fins 3 c 2.

The permeable metal is a metal material that is formed by connecting space portions (pores) of porous metal to each other and allows a gas to pass through the inside thereof. Since the tip portions of the seal fins 3 c 2 can be in contact with the respective permeable spacers 4, the minimum clearances are provided. It is therefore possible to improve the properties of seals between the seal fins 3 c 2 and the rotor 2 a.

As described above, the following technique is known. That is, the technique is to remove or reduce a clearance between each seal fin 3 c 2 and the rotor 2 a and a clearance between each seal fin 2 a 1 and the seal stationary body 3 c 1 for improvement of the seal property and provide a spacer (made of a material (such as an abradable material) having an excellent cutting property) on a portion (facing the tip portion of the seal fin 3 c 2) of the rotor 2 a and provide a spacer (made of a material (such as an abradable material) having an excellent cutting property) on a portion (facing the seal fin 2 a 1) of the seal stationary body 3 c 1. In this known technique, however, heat generated by frictions between the seal fins 3 c 2 and the spacers that rotate with the rotor 2 a is transferred to the rotor 2 a. Then, the temperature of the rotor 2 a increases. The rotor 2 a may be transformed (e.g., may be bent) by heat due to a nonuniform temperature distribution of the rotor 2 a, and a rotor shaft may vibrate.

It is also known that a heat insulating material is provided between the seal fin 3 c 2 and the rotor 2 a, and a heat insulating material is provided between the seal fin 2 a 1 and the seal stationary body 3 c 1. In this technique, when the rotor 2 a continuously rotates for a long period of time, and the spacer that rotates with the rotor 2 a is in contact with the seal fin 3 c 2 for a long period of time, heat generated by a friction between the seal fin 3 c 2 and the spacer is gradually accumulated. As a result, the temperature of the heat insulating layer increases. Then, the heat of the heat insulating layer is transferred to the rotor 2 a. The temperature of the rotor 2 a increases. The rotor 2 a may be transformed (e.g., may be bent) by heat due to a nonuniform temperature distribution of the rotor 2 a.

On the other hand, an extremely small amount of the steam St passes through the inside of each of the permeable spacers 4 made of the permeable metal in the present embodiment, as shown in FIG. 3.

The temperatures of the permeable spacers 4 are uniformly maintained to the same temperature as that of the steam St by the steam St (that passes through the inside of each permeable spacer 4). The temperatures of the permeable spacers 4 are not higher than that of the steam St.

The amount of the steam St that passes through the inside of each permeable spacers 4 needs to be set to ensure that the seal property are not affected and the temperatures of the permeable spacers 4 are maintained to be the same as the temperature of the steam St. The amount of the steam St that passes through the permeable metal (forming each permeable spacer 4) is extremely small. The amount of the steam St that passes through the permeable metal is determined based on the density and sizes of the pores. It is only necessary to use a permeable metal ensuring the steam amount that does not affect the seal property and allows the temperatures of the permeable spacers 4 to be maintained to the same level as the temperature of the steam St.

Since the temperatures of the permeable spacers 4 are maintained to be the same as the temperature of the steam St, the temperatures of the permeable spacers 4 do not become higher than the temperature of the steam St even when the rotor 2 a continuously rotates for a long period of time and the seal fins 3 c 2 are in contact with the permeable spacers 4 (that rotate with the rotor 2 a) for a long period of time. This configuration can suppress an increase in the temperature of the rotor 2 a to a level higher than the temperature of the steam St. The rotor 2 a is designed to be resistant to the temperature of the steam St. Therefore, when the temperature of the rotor 2 a is maintained to be the same as that of the steam St, the rotor 2 a is not transformed by heat (e.g., the rotor 2 a is not transformed by excessive heat stress or is not bent due to the heat) and does not interfere with an operation of the steam turbine 2 (refer to FIG. 1).

The permeable spacers 4 may be provided on either one of the side of the rotor 2 a and the side of the seal stationary body 3 c 1 in the labyrinth seal device 3 c shown in FIG. 2B.

The amount of the steam St that passes through each permeable spacer 4 is small compared with the amount of the steam leaking from the clearance provided between each seal fin 3 c 2 and the rotor 2 a. The amount of the steam St that passes through each permeable spacer 4 does not affect the turbine efficiency of the steam turbine 2 (refer to FIG. 1).

The embodiment in which the permeable spacers 4 are provided in the labyrinth seal device 3 c is described above. The present invention is not limited to this configuration. For example, the labyrinth seal device 3 c may be a high-low labyrinth seal device in addition to the configuration shown in FIG. 2B. The present invention can be applied to the high-low labyrinth seal device. FIGS. 4A and 4B are diagrams each showing a high-low labyrinth seal device. FIG. 4A shows the high-low labyrinth seal device in which the seal stationary body has seal fins. FIG. 4B shows the high-low labyrinth seal device in which the rotor has seal fins.

The seal stationary body 3 c 1 of the high-low labyrinth seal device 3 c shown in FIG. 4A has a plurality of the seal fins 3 c 4. The labyrinth seal device 3 c shown in FIG. 4A is engaged with and fixed to the nozzle diaphragm inner ring 3 a. The rotor 2 a shown in FIG. 4A has a plurality of protruding portions 2 a 3 and recessed portions 2 a 4. The protruding portions 2 a 3 are provided at a circumferential portion of the rotor 2 a. Each of the recessed portions 2 a 4 is located between the protruding portions 2 a 3. The seal fins 3 c 4 face the respective protruding portions 2 a 3 of the rotor 2 a and recessed portions 2 a 4.

As shown in FIG. 4A, the air-permeable spacers 4 are provided on the protruding portions 2 a 3 of the rotor 2 a and on the recessed portions 2 a 4 of the rotor 2 a and face the respective seal fins 3 c 4. The permeable spacers 4 can serve to improve the seal property between the seal fins 3 c 4 and the rotor 2 a.

The permeable spacers 4 may be provided on either the protruding portions 2 a 3 of the rotor 2 a or the recessed portions 2 a 4 of the rotor 2 a in the high-low labyrinth seal device 3 c.

As shown in FIG. 4B, the high-low labyrinth seal device 3 c may have a structure in which the seal fins 2 a 5 are provided at the circumferential portion of the rotor 2 a. In this case, the seal stationary body 3 c 1 has recessed portions and protruding portions. The recessed portions and protruding portions of the seal stationary body 3 c 1 face the respective seal fins 2 a 5. As shown in FIG. 4B, the permeable spacers 4 are provided on the recessed portions and protruding portions of the seal stationary body 3 c 1. Alternatively, the permeable spacers 4 may be provided on either the recessed portions of the seal stationary body 3 c 1 or the protruding portions of the seal stationary body 3 c 1.

In the description above, the permeable spacers 4 are provided for the labyrinth seal device 3 c that is located between the stator blade 2 c and the rotor 2 a, as shown in FIG. 2A. The permeable spacers 4 may be provided at a tip portion of each rotor blade 2 b.

FIG. 5 is a schematic diagram showing the tip portion of the rotor blade 2 b. As shown in FIG. 5, a cover 2 g is provided on the tip portion of the rotor blade 2 b. The cover 2 g serves to reduce a clearance between the rotor blade 2 b and the nozzle diaphragm outer ring 3 b. The nozzle diaphragm outer ring 3 b has seal fins 3 b 1 and faces the cover 2 g.

The permeable spacers 4 are provided on the cover 2 g and face the respective seal fins 3 b 1.

In this structure, even when the rotor blade 2 b rotates to ensure that the seal fins 3 b 1 contact the permeable spacers 4 and that frictional heat generated by the contacts causes the permeable spacers 4 to increase in temperature, the temperatures of the permeable spacers 4 are not higher than the temperature of the steam St due to the steam St that passes through the insides of the permeable spacers 4. Therefore, the temperatures of the rotor blades 2 b do not become higher than those of the steams St.

The seal fins may be provided at the tip portion of each rotor blade. FIG. 6 is a diagram showing a structure in which the seal fins are provided at the tip portion of the rotor blade. FIG. 7 is a diagram showing a structure in which the seal fins are provided on the nozzle diaphragm outer ring and the seal fins are provided at the tip portion of the rotor blade.

As shown in FIG. 6, for example, the seal fins 2 b 1 may be provided at the tip portion of each rotor blade 2 b (or on the cover 2 g). In this structure, the permeable spacers 4 are provided on the nozzle diaphragm outer ring 3 b and face the respective seal fins 2 b 1.

As shown in FIG. 7, the seal fins 3 b 2 may be provided on the nozzle diaphragm outer ring 3 b, and the seal fins 2 b 2 may be provided at the tip portion of each rotor blade 2 b. In this structure, the permeable spacers 4 are provided on the nozzle diaphragm outer ring 3 b, and the other permeable spacers 4 are provided at the tip portion of each rotor blade 2 b (or on the cover 2 g).

When the seal fins 3 b 2 are provided at the nozzle diaphragm outer ring 3 b and the seal fins 2 b 2 are provided at the tip portion of each rotor blade 2 b (or the seal fins 2 b 2 are provided on the cover 2 g), the permeable spacers 4 may be provided either on the nozzle diaphragm outer ring 3 b or at the tip portion of each rotor blade 2 b (or on the cover 2 g).

The permeable spacers 4 may be provided at locations at which a rotating portion (such as the rotor 2 a (refer to FIG. 2A) and a fixed portion (such as the casing 2 d (refer to FIG. 2A) are in contact with each other. It is possible to improve the seal property since the rotating portion is not subjected to high temperature steam.

In each of the structures described above, the amount of the steam that passes through the permeable spacers 4 can be properly set in consideration of the seal property and a cooling property. 

1. A seal structure for a steam turbine, comprising a plurality of seal fins provided at least one of a rotating portion and a fixed portion, the rotating portion being composed of a rotor of the steam turbine and members that rotate with the rotor, the fixed portion being composed of a casing and members fixed to the casing, the casing containing the rotating portion, wherein spacers made of a permeable metal are provided on at least one of the rotating portion and the fixed portion and face the respective seal fins.
 2. The seal structure for the steam turbine according to claim 1, wherein the members fixed to the casing are stator blades fixed to the casing, both or either tip portions of the stator blades or the rotor have or has the seal fins, the seal fins facing the tip portions of the respective stator blades when the rotor has the seal fins, and both or either the tip portions of the stator blades or the rotor have or has thereon the spacers made of the permeable metal, the spacers facing the respective the seal fins.
 3. The seal structure for the steam turbine according to claim 1, wherein the members that rotate with the rotor are rotor blades of the rotor, both or either the casing or the tip portions of the rotor blades have or has the seal fins, the seal fins facing the tip portions of the respective rotor blades when the casing has the seal fins, and both or either the casing and the tip portions of the rotor blades have or has thereon the spacers made of the permeable metal, the spacers facing the respective seal fins.
 4. The seal structure for the steam turbine according to claim 2, wherein the members that rotate with the rotor are rotor blades of the rotor, both or either the casing or the tip portions of the rotor blades have or has the seal fins, the seal fins facing the tip portions of the respective rotor blades when the casing has the seal fins, and both or either the casing and the tip portions of the rotor blades have or has thereon the spacers made of the permeable metal, the spacers facing the respective seal fins. 